NIST Projects in Human Identity Testing
Peter ValloneJohn Butler, Margaret Kline, Mike Coble
Jan Redman, Amy Decker, Becky Hill, Chris DeAngelisDave Duewer (NIST Analytical Chemistry Division)
AFDAA Summer Meeting Austin, TX August 4, 2005
AMELD3
TH01 TPOX
D2D19FGA
D21 D18
CSFD16
D7D13
D5 VWAD8
NIST Human Identity Project Team
Mike CoblePete ValloneJohn Butler(Project Leader)
Margaret Kline
Amy Decker Becky HillDave DuewerAnal. Chem. Division
Jan Redman
Funding: Interagency Agreement 2003-IJ-R-029 between National Institute of Justice (NIJ) and NIST Office of Law Enforcement Standards (OLES)
Chris DeAngelis
Current Areas of NIST Research Effort
• Resources for “Challenging Samples” (miniSTRs)
• Information on New Loci (SNPs, Y-Chromosome, new STRs)
• Standard Information Resources (STRBase website, training materials/review articles, validation standardization)
• Allele Sequencing and Interlaboratory Studies(Real-time qPCR, mixture interpretation)
miniSTRs for Degraded DNA
• Original miniSTR paper with CODIS loci, D2, D19, Penta D, Penta E– Butler et al. (2003) J. Forensic Sci. 48: 1054-1064
• Many CODIS loci are too big and make poor miniSTRs
• New miniSTRs and assays: NC01, NC02– Coble, M.D. and Butler, J.M. (2005) J. Forensic Sci. 50:43-53
• New miniSGM miniplex: AMEL, TH01, FGA, D18, D16, D2
• Creation of miniSTR information on STRBase
http://www.cstl.nist.gov/biotech/strbase/miniSTR.htm
Mike Coble
Becky Hill
John Butler
STR repeat regionminiSTR primer
miniSTR primer
Conventional PCR primer
Conventional PCR primer
Conventional STR test (COfiler™ kit)
MiniSTR assay (using Butler et al. 2003 primers)
A miniSTR is a reduced size STR amplicon that enables higher recovery of information from degraded DNA samples
Butler, J.M. (2005) Forensic DNA Typing, 2nd Edition, Figure 7.2, ©Elsevier Science/Academic Press
~150 bp smaller
Testing must be performed to show allele concordance between primer sets
Testing must be performed to show allele concordance between primer sets
New miniSGM miniplex assay
TH01Amelogenin FGA
D18S51
D16S539
D2S1338
200 bp100 bp
-71 bp-71 bp
+20 bp+20 bp
-151 bp-151 bp-105 bp-105 bp
-152 bp-152 bp
-198 bp-198 bp
Size relative to ABI kits
New combination of miniSTR loci:Loci with highest PD (D2S1338, D18S51, FGA)Extra European concordance (TH01, D16S539)Sex-typing added (amelogenin)
Retains same miniSTR primers from Butler et al. (2003) J. Forensic Sci 48(5): 1054-1064
Provided to EDNAP/ENFSI group for degraded DNA study (Fall 2004)
Many CODIS Loci Make Poor miniSTRs
• Large allele range (e.g., FGA)
• Large alleles (e.g., D21S11 and FGA)
• Poor flanking regions prohibiting reliable primer annealing immediately adjacent to the repeat region (e.g., D7S820)
“STRs have proven to be highly successful [formass disasters] in the past e.g. Waco disasterand various air disasters. However, even if theDNA is high quality there are occasions whenthere are insufficient family members availableto achieve a high level of confidence with anassociation.”
Gill, P., Werrett, D.J., Budowle, B. and Guerrieri, R. (2004) An assessment of whether SNPs will replace STRs in national DNA databases-Joint considerations of the DNA working group of the European Network of Forensic Science Institutes (ENFSI) and the Scientific Working Group on DNA Analysis Methods (SWGDAM). Science&Justice, 44(1): 51-53.
Why go beyond CODIS loci
“To achieve this purpose, either new STRs could be developed, or alternatively, existing STRs could be supplemented with a SNP panel.”
“There are also efforts for modifying existing STR panels by decreasing the size amplicons by designing new primers.”
Gill, P., Werrett, D.J., Budowle, B. and Guerrieri, R. (2004) An assessment of whether SNPs will replace STRs in national DNA databases-Joint considerations of the DNA working group of the European Network of Forensic Science Institutes (ENFSI) and the Scientific Working Group on DNA Analysis Methods (SWGDAM). Science&Justice, 44(1): 51-53.
Why go beyond CODIS loci
• Desirable to have markers unlinked from CODIS loci (different chromosomes) for some applications
• Small size ranges to aid amplification from degraded DNA samples
• New miniSTR loci will benefit missing persons investigations and paternity testing (and perhaps national databases in the future)
Why go beyond CODIS loci
Characterization of New miniSTR Loci
• Candidate STR marker selection• Chromosomal locations and marker
characteristics• PCR primer design• Initial testing results• Population testing• Allelic ladder construction• Miniplex assay performance
Initial Testing Results with Potential miniSTR Loci
Coble and Butler (2005) J. Forensic Sci. 50(1): 43-53
NC01
7 miniplexes (21 markers) are currently
under investigation
Based on observed allele rangeHeterozygosity
NC02
Ref. Amplicon Primer distance Chr. Marker Name (Motif) Repeat Size from repeat
10 D10S1248 TETRA 13 102 1 GGAA23C05N GGAA 0
14 D14S1434 TETRA 10 88 1 GATA168F06 GATA 0
22 D22S1045 TRI 13 105 3 ATA37D06 ATA 6
1 D1S1677 TETRA 15 103 0 GGAA22G10N GGAA 0
2 D2S441 TETRA 12 92 0GATA8F03 GATA 0
4 D4S2364 TETRA 7 78 2 GAAT1F09 GAAT 1
D10S1248
D14S1434
D22S1045
Miniplex NC01
D4S2364
D2S441
D1S1677
Miniplex NC02
Some Marker Characteristics
Coble and Butler (2005) J. Forensic Sci. 50(1): 43-53
1 2
3 4 5 6
7 8 9 10 11 12
13 14 15 16 17 18
19 20 21 22
X
Y
mD22S1045
mD14S1434
mD4S2364
mD2S441
mD1S1677
mD10S1248
VWA
TPOX
TH01
SE33
Penta E
Penta D
LPL
FGA
FES/FPS
F13B
F13A1
D8S1179
D7S820
D5S818
D3S1358
D2S1338
D21S11D19S433
D18S51D16S539D13S317
CSF1PO
AMEL_Y
AMEL_X
Chromosome
Loca
tion
STR Loci Positions (including CODIS 13 STRs)
Positions determined along May 2004 Human Genome Reference Sequence (NCBI Build 35)
Stock tubes
extracted genomic DNA
To date: (~95,000 allele calls)Identifiler (15 autosomal markers + Amelogenin) (10,608)Roche Linear Arrays (HV1/HV2 10 regions) (6,630)Y STRs 22 loci—27 amplicons (17,388)Y STRs 27 new loci (14,535)Yfiler kit 17 loci (11,237)Y SNPs 50 markers on sub-set of samples (11,498)Orchid 70 autosomal SNPs on sub-set (13,230)miniSTR testing-new loci and CODIS concordance (9,228)mtDNA full control region sequences by AFDIL
DNA extracted from whole blood (anonymous; self-identified ethnicities) received from Interstate Blood Bank (Memphis, TN) and Millennium Biotech Inc. (Ft. Lauderdale, FL)
Standard U.S. Population Datasethttp://www.cstl.nist.gov/biotech/strbase/NISTpop.htm
260 Caucasians, 260 African Americans, 140 Hispanics, 3 Asians = 663 males
Genotypes with various human identity testing
markers
6FAM (blue)
(blue)
VIC (green)
(green)
NED (yellow)
(yellow)
D10S1248
D22S1045
D14S1434
PCR Product Size (bp)
D14S1434
D10S1248
D22S1045
NIST Allelic Ladders
.
Allele Ladders for Miniplex "NC01"
Coble and Butler (2005) Characterization of new miniSTR loci to aid analysis of degraded DNA J. Forensic Sci. 50(1): 43-53
http://www.cstl.nist.gov/biotech/strbase/miniSTR.htm
miniSTR Assay Sensitivity (D10S1248)
200 pg
100 pg
50 pg
20 pg
10 pg
5 pg
28 cycles – 1U Taq 32 cycles – 2U Taq
Primer Sequences
Pos. Control Results
PCR Conditions
http://www.cstl.nist.gov/biotech/strbase/miniSTR/miniNC01_Protocol.pdf
New Autosomal miniSTR Loci
• NC01 loci: D10S1248, D14S1434, D22S1045
• Peter Gill and the EDNAP/ENFSI group have recommended the NC01 loci as an extension of current European core loci
• Population data, locus characterization, and allelic ladders for 27 new autosomal STRs under development as new miniSTRs
• All new STR loci are physically unlinked to CODIS core loci
http://www.cstl.nist.gov/biotech/strbase/newSTRs.htm
Work with SNP Loci
• U.S. population frequencies with 70 autosomal SNPs– Vallone et al. (2005) Forensic Sci. Int. 149: 279-286
• U.S. population information with 50 Y-SNPs– Vallone et al. (2004) J. Forensic Sci. 49: 723-732
• Coding Region Mitochondrial SNPs– Vallone et al., (2004) Int. J. Legal Med. 118: 147-157
• Construction of 12plex autosomal SNP assay
http://www.cstl.nist.gov/biotech/strbase/SNP.htm
Pete Vallone
Amy Decker
John Butler
SNPs
Why are we interested in using SNPs?
•Use on degraded samples (WTC), low copy number, or telogenic (shed) hairs•Lower mutation rate (Paternity testing)•Easier data interpretation (no microvariants or stutter)•Amenable to high throughput analysis
SNPs
General issues that need to be addressed
•How many SNPs = STR•Multiplexing (50-plex < 1ng DNA)•Databases•Platform for SNP typing?•Unique interpretation issues – mixtures•Validation•Sensitivity•Cost
Target region (short tandem repeat)
7 repeats
8 repeats
9 repeats
10 repeats
11 repeats
12 repeats
13 repeats
C
T
Target region (single nucleotide
polymorphism)
miniSTR
Conventional STR
Smaller target regionFewer possible variantsNeed more SNP markersConstant size examined
Larger target region (miniSTR targets same region)More possible variants than SNPsOnly need a moderate number of STR markersRange of sizes examined (e.g., 28 bp spread if 4 bp/repeat)
SNP
Comparison of STRs and SNPs
SNP Typing Instrumentation
Luminex 100 Flow CytometerMulti-Color Capillary Electrophoresis (ABI 310 or 3100)
Time-of-Flight Mass Spectrometer
PCR & primer extensionPCR & primer extension
ABI 7000 SDS
TaqManTaqMan
Luminex Beadshybridization
Luminex Beadshybridization
Primer ExtensionPrimer Extension
PCR Amplified DNA TemplateG
SNP Primer is extended by one base unit
Allele-Specific Primer Extension
Oligonucleotide primer 18-28 bases5’ 3’
“tail” used to vary electrophoretic mobility G
CA
T
Fluorescently labeled ddNTPs + polymerase
ABI PRISM® SNaPshot™ Multiplex System
ddNTP Dye label ColorA dR6G GreenC dTAMRA BlackG dR110 BlueT dROX Red
25 Cycles96oC 10s50oC 5s60oC 30s
Utility of SNP Markers
Replace Autosomal STRs?“It is unlikely that SNPs will replace STRs as the preferred method of testing of forensic samples in the near to medium future.”
Specialized applicationsmtDNA – coding region and linear arraysY-SNPs – lineage, population study, sample discriminationAutosomal SNPs – highly degraded samples, shed hairs, physical characteristics, ethnic/geographical determination
Gill, P., Werret, D.J., Budowle, B., and Guerreri, R. Science and Justice 2004 44: 51-53
70 were typed for 189 U.S. samples (self identified ethnicities)74 Caucasians + 71 African Americans AA + 44 Hispanics
Total of 13,230 possible genotypes
42 Samples were re-injected to confirm ambiguous results (99.7 %) success rate on first passAllele distribution ranged from (0.25 – 0.74)P-value was < 5% for 10 lociResults described in manuscript (Vallone, P.M., Decker, A.E., Butler, J.M. (2005) Forensic Sci. Int., 2005)
Results on a 12-plex panel of SNPs to follow…
SNP Assay Results
Allele Frequencies for 70 SNP Loci in U.S. PopulationsHispanic N = 44 1 2 3 4 5 6 7 8 9 10 11 12
CC 0.455 0.477 0.114 0.364 0.364 0.045 0.432 0.182 0.227 0.091 0.182 0.205TT 0.068 0.045 0.341 0.136 0.136 0.432 0.114 0.386 0.273 0.409 0.341 0.341CT 0.477 0.477 0.545 0.500 0.500 0.523 0.455 0.432 0.500 0.500 0.477 0.455He 0.425 0.407 0.474 0.474 0.474 0.425 0.449 0.479 0.499 0.449 0.487 0.491p 0.723 0.441 0.522 1.000 1.000 0.177 1.000 0.545 1.000 0.741 1.000 0.724
13 14 15 16 17 18 19 20 21 22 23 24CC 0.068 0.341 0.500 0.386 0.114 0.295 0.477 0.273 0.136 0.091 0.250 0.273TT 0.568 0.205 0.091 0.159 0.545 0.318 0.068 0.205 0.364 0.455 0.364 0.273CT 0.364 0.455 0.409 0.455 0.341 0.386 0.455 0.523 0.500 0.455 0.386 0.455He 0.375 0.491 0.416 0.474 0.407 0.500 0.416 0.498 0.474 0.434 0.494 0.500p 1.000 0.777 1.000 0.782 0.311 0.135 0.719 1.000 1.000 1.000 0.226 0.565
25 26 27 28 29 30 31 32 33 34 35 36CC 0.318 0.205 0.227 0.091 0.227 0.114 0.523 0.477 0.136 0.568 0.182 0.318TT 0.114 0.455 0.227 0.682 0.364 0.295 0.182 0.091 0.432 0.091 0.318 0.227CT 0.568 0.341 0.545 0.227 0.409 0.591 0.295 0.432 0.432 0.341 0.500 0.455He 0.479 0.469 0.500 0.325 0.491 0.483 0.442 0.425 0.456 0.386 0.491 0.496p 0.326 0.097 0.766 0.063 0.365 0.198 0.036 1.000 0.752 0.435 1.000 0.558
37 38 39 40 41 42 43 44 45 46 47 48CC 0.523 0.045 0.455 0.114 0.295 0.250 0.205 0.523 0.091 0.136 0.205 0.477TT 0.045 0.568 0.091 0.477 0.159 0.136 0.432 0.023 0.455 0.318 0.477 0.023CT 0.432 0.386 0.455 0.409 0.545 0.614 0.364 0.455 0.455 0.545 0.318 0.500He 0.386 0.363 0.434 0.434 0.491 0.494 0.474 0.375 0.434 0.483 0.463 0.397p 0.694 1.000 1.000 0.727 0.542 0.135 0.119 0.248 1.000 0.522 0.048 0.143
49 50 51 52 53 54 55 56 57 58 59 60CC 0.068 0.318 0.227 0.29545 0.159 0.250 0.409 0.500 0.182 0.023 0.136 0.182TT 0.636 0.227 0.318 0.25 0.341 0.295 0.136 0.068 0.455 0.636 0.500 0.250CT 0.295 0.455 0.455 0.45455 0.500 0.455 0.455 0.432 0.364 0.341 0.364 0.568He 0.339 0.496 0.496 0.499 0.483 0.499 0.463 0.407 0.463 0.312 0.434 0.498p 0.381 0.562 0.563 0.576 1.000 0.558 1.000 1.000 0.168 1.000 0.294 0.564
61 62 63 64 65 66 67 68 69 70CC 0.068 0.409 0.205 0.205 0.386 0.432 0.295 0.295 0.273 0.318TT 0.455 0.091 0.341 0.205 0.227 0.182 0.227 0.227 0.227 0.205CT 0.477 0.500 0.455 0.591 0.386 0.386 0.477 0.477 0.500 0.477He 0.425 0.449 0.491 0.500 0.487 0.469 0.498 0.498 0.499 0.494p 0.721 0.744 0.777 0.383 0.191 0.336 0.797 0.754 1.000 1.000
African AmericanN = 71 1 2 3 4 5 6 7 8 9 10 11 12
CC 0.648 0.113 0.141 0.352 0.141 0.127 0.648 0.183 0.225 0.014 0.070 0.394TT 0.070 0.352 0.437 0.141 0.338 0.563 0.070 0.408 0.338 0.662 0.549 0.155CT 0.282 0.535 0.423 0.507 0.521 0.310 0.282 0.408 0.437 0.324 0.380 0.451He 0.333 0.471 0.456 0.478 0.481 0.405 0.333 0.475 0.494 0.290 0.385 0.471p 0.278 0.207 0.441 0.808 0.468 0.043 0.275 0.226 0.225 0.680 0.760 0.624
13 14 15 16 17 18 19 20 21 22 23 24CC 0.141 0.296 0.239 0.479 0.113 0.113 0.634 0.197 0.070 0.028 0.282 0.268TT 0.451 0.113 0.338 0.085 0.479 0.451 0.042 0.366 0.606 0.648 0.239 0.239CT 0.408 0.592 0.423 0.437 0.408 0.437 0.324 0.437 0.324 0.324 0.479 0.493He 0.452 0.483 0.495 0.422 0.433 0.443 0.325 0.486 0.357 0.308 0.499 0.500p 0.298 0.093 0.158 0.784 0.396 1.000 0.720 0.469 0.326 1.000 0.644 1.000
25 26 27 28 29 30 31 32 33 34 35 36CC 0.099 0.394 0.239 0.225 0.113 0.352 0.380 0.113 0.197 0.493 0.113 0.352TT 0.394 0.155 0.254 0.282 0.451 0.169 0.183 0.423 0.338 0.042 0.535 0.197CT 0.507 0.451 0.507 0.493 0.437 0.479 0.437 0.465 0.465 0.465 0.352 0.451He 0.456 0.471 0.500 0.498 0.443 0.483 0.481 0.452 0.490 0.398 0.411 0.488p 0.310 0.606 1.000 1.000 1.000 0.805 0.315 0.799 0.645 0.234 0.157 0.622
37 38 39 40 41 42 43 44 45 46 47 48CC 0.324 0.211 0.113 0.141 0.113 0.225 0.056 0.606 0.380 0.211 0.099 0.380TT 0.183 0.366 0.592 0.465 0.549 0.310 0.479 0.056 0.183 0.366 0.465 0.169CT 0.493 0.423 0.296 0.394 0.338 0.465 0.465 0.338 0.437 0.423 0.437 0.451He 0.490 0.488 0.385 0.448 0.405 0.496 0.411 0.349 0.481 0.488 0.433 0.478p 1.000 0.335 0.061 0.182 0.159 0.639 0.256 0.488 0.331 0.336 0.786 0.625
49 50 51 52 53 54 55 56 57 58 59 60CC 0.085 0.465 0.310 0.099 0.423 0.282 0.211 0.408 0.042 0.239 0.282 0.352TT 0.549 0.070 0.099 0.648 0.169 0.141 0.310 0.141 0.535 0.225 0.183 0.211CT 0.366 0.465 0.592 0.254 0.408 0.577 0.479 0.451 0.423 0.535 0.535 0.437He 0.392 0.422 0.478 0.349 0.468 0.490 0.495 0.464 0.378 0.500 0.495 0.490p 0.369 0.401 0.081 0.030 0.307 0.221 0.626 0.616 0.532 0.633 0.475 0.337
61 62 63 64 65 66 67 68 69 70CC 0.310 0.352 0.268 0.479 0.183 0.423 0.592 0.380 0.338 0.296TT 0.225 0.141 0.183 0.099 0.310 0.169 0.113 0.113 0.197 0.141CT 0.465 0.507 0.549 0.423 0.507 0.408 0.296 0.507 0.465 0.563He 0.496 0.478 0.496 0.428 0.492 0.468 0.385 0.464 0.490 0.488p 0.634 0.803 0.469 0.786 1.000 0.296 0.059 0.459 0.626 0.226
Caucasian N = 74 1 2 3 4 5 6 7 8 9 10 11 12
CC 0.243 0.405 0.068 0.581 0.311 0.149 0.486 0.108 0.203 0.068 0.257 0.054TT 0.243 0.135 0.514 0.135 0.189 0.338 0.122 0.378 0.284 0.459 0.216 0.365CT 0.514 0.459 0.419 0.284 0.500 0.514 0.392 0.514 0.514 0.473 0.527 0.581He 0.500 0.463 0.401 0.401 0.493 0.482 0.433 0.463 0.497 0.423 0.499 0.452p 0.816 1.000 1.000 0.008 0.816 0.475 0.413 0.305 1.000 0.269 0.818 0.021
13 14 15 16 17 18 19 20 21 22 23 24CC 0.068 0.243 0.392 0.446 0.243 0.162 0.473 0.365 0.270 0.108 0.270 0.203TT 0.514 0.311 0.122 0.149 0.284 0.324 0.054 0.203 0.189 0.432 0.176 0.270CT 0.419 0.446 0.486 0.405 0.473 0.514 0.473 0.432 0.541 0.459 0.554 0.527He 0.401 0.498 0.463 0.456 0.499 0.487 0.412 0.487 0.497 0.447 0.496 0.498p 1.000 0.220 0.805 0.183 0.663 0.818 0.163 0.348 0.485 1.000 0.362 0.650
25 26 27 28 29 30 31 32 33 34 35 36CC 0.243 0.176 0.162 0.068 0.257 0.432 0.419 0.527 0.122 0.581 0.257 0.108TT 0.203 0.446 0.432 0.689 0.284 0.149 0.122 0.122 0.311 0.068 0.203 0.243CT 0.554 0.378 0.405 0.243 0.459 0.419 0.459 0.351 0.568 0.351 0.541 0.649He 0.499 0.463 0.463 0.307 0.500 0.460 0.456 0.418 0.482 0.368 0.499 0.491p 0.480 0.135 0.327 0.119 0.350 0.302 0.797 0.092 0.088 0.538 0.642 0.008
37 38 39 40 41 42 43 44 45 46 47 48CC 0.378 0.095 0.378 0.149 0.297 0.311 0.257 0.473 0.122 0.189 0.162 0.351TT 0.122 0.473 0.149 0.514 0.216 0.149 0.216 0.095 0.446 0.284 0.351 0.162CT 0.500 0.432 0.473 0.338 0.486 0.541 0.527 0.432 0.432 0.527 0.486 0.486He 0.467 0.428 0.474 0.433 0.497 0.487 0.499 0.428 0.447 0.496 0.482 0.482p 0.444 0.790 0.806 0.060 0.827 0.491 0.822 0.791 0.790 0.635 0.803 0.802
49 50 51 52 53 54 55 56 57 58 59 60CC 0.137 0.205 0.178 0.356 0.096 0.288 0.446 0.419 0.149 0.081 0.081 0.351TT 0.562 0.370 0.247 0.178 0.534 0.192 0.135 0.108 0.392 0.662 0.527 0.203CT 0.301 0.425 0.575 0.466 0.370 0.521 0.419 0.473 0.459 0.257 0.392 0.446He 0.410 0.486 0.498 0.484 0.404 0.495 0.452 0.452 0.470 0.331 0.401 0.489p 0.040 0.230 0.226 0.630 0.401 0.639 0.472 0.612 0.618 0.068 0.785 0.331
61 62 63 64 65 66 67 68 69 70CC 0.068 0.473 0.189 0.162 0.233 0.378 0.486 0.324 0.216 0.284TT 0.608 0.027 0.486 0.284 0.219 0.162 0.054 0.108 0.351 0.149CT 0.324 0.500 0.324 0.554 0.548 0.459 0.459 0.568 0.432 0.568He 0.354 0.401 0.456 0.493 0.500 0.477 0.407 0.477 0.491 0.491p 0.326 0.043 0.011 0.232 0.500 0.805 0.401 0.142 0.346 0.263
Vallone et al. (2005) Forensic Sci. Int. 149:279-286
NIST Autosomal 12plex SNP Assay
CHR:13 15 10 01 17 13 17 01 06 11 20 15
12plex PCR followed by 12-plex ASPEFragments separated on a ABI 3100 in 35 minutesA Genotyper macro has been developed to type dataThe 12plex assay has been run on over 600 samples Works well on 0.5 to 1 ng of templateSensitivity studies are underway
C/T
C/C
T/T Best 12 SNPs selected from 70 originally tested
G/A
C/T
C/C C/C C/C
C/C C/CT/T T/T
SNaPshot resultVallone, P.M., Decker, A.E., Butler, J.M. (2005) Allele frequencies for 70 autosomal SNP loci with U.S. Caucasian, African American, and Hispanic Samples. Forensic Sci. Int. 149:279-286.
# of SNPs # of Genotypes1 32 93 274 645 1076 1457 1608 1759 18210 18611 18812 189
neg
2 ng
1 ng
500 pg
Sensitivity Study
32 cycles PCR; 1.5 U Taq Gold
250 pg
125 ng
63 pg
31 pg
Sensitivity Study
Genemapper ID v3.2
Buccal Control
14 pg
91 pg
148 pg
210 pg
Enzymatic digestion protocolExtracts quantified using ABI Quantifiler
Results for typing shed hairs
0
20
40
60
80
100
120
140
N (n
umbe
r of i
ndiv
idua
ls)
<1.0e
+04
<2.5e
+06
<5.0e
+06
<1.0e
+06
<5.0e
+05
<1.0e
+05
<8.5+
06
Probability of a Random Match using 12-plex
AA (N = 259)Cauc (N = 264)Hisp (N = 139)
for unrelated individuals
1 in 67,000 – 78,000
Expressed as 1 in …
Roche Linear Arrays(probes for HVI/HVII)
Automated washing/Population Study
NIST mtDNA WorkCoding Region mtSNP 11plex
(minisequencing assay)
Developed with AFDIL to resolve mtDNA most
common types
Int. J. Legal Med., 2004;118: 147-157
J. Forensic Sci. 2005, 50(2): 377-385
Summary of Our Population Typing with Roche mtDNA
LINEAR ARRAYS
4.20.4128
1.80.4112
2.70.4118
3.50.4123
7.70.4151
1.70.4111
6.01.4410
2.70.729
10.83.298
1.10.417
3.61.446
2.31.135
2.41.444
8.16.4183
13.816.3462
27.865.61851
% People% TypesFreq#*
•282 different types •185 were unique (occurred only once)•51 samples had “Most Common Type”
Typing frequencies for 666 NIST population samples
“Most Common Type” evaluated further with mtDNA coding region SNP assay
Affymetrix Genechip Mitochondrial Resequencing Array (2nd gen)
Interrogates >12,000 bases (coding region)Less than 48h3 long PCR ampliconsDetection of heteroplasmy
We will be testing 3 - 4 NIST population samples that have been sequenced by AFDIL
Forensic SNP Sitenow a part of
STRBase
Work with Y-STRs
• Beta-testing of all commercial Y-STR kits
• Population data supplied to Yfiler haplotype database
• 49 Y-STR loci evaluated with ~650 U.S. samples
• New Y-chromosome information on STRBase linking to all available haplotype databases
• Nomenclature defined for new loci
• Human Y-Chromosome DNA Profiling Standard Reference Material (SRM 2395) – updates with DYS635 for Yfiler
• Separation of two brothers with 47 Y-STRshttp://www.cstl.nist.gov/biotech/strbase/y_strs.htm
John Butler
Margaret Kline
Amy Decker
Pete Vallone
Y-Chromosome Standard NIST SRM 2395
Human Y-Chromosome DNA Profiling Standard
•5 male samples + 1 female sample (neg. control)
•100 ng of each (50 µL at ~2 ng/µL)
•22 Y STR markers sequenced
•9 additional Y STR markers typed
•42 Y SNPs typed with Marligen kit
C
B
A D
E
FCertified for all loci in commercial Y-STR kits:
Y-PLEX 6Y-PLEX 5Y-PLEX 12PowerPlex Y
SWGDAM recommended loci:DYS19, DYS385 a/b, DYS389I/II, DYS390, DYS391, DYS392, DYS393, DYS438, DYS439
SWGDAM recommended loci:DYS19, DYS385 a/b, DYS389I/II, DYS390, DYS391, DYS392, DYS393, DYS438, DYS439
Helps meet FBI Standard 9.5 (and ISO 17025)…traceability to a national standard
Y-filer - adds DYS635 (C4); now sequenced
Evaluation of qPCR Assays
• Evaluation of published assays on same samples
• Characterization of DNA Standard lot-to-lot performance
• Additional studies under way utilizing qPCR:– Examining the challenge of multiplexing qPCR assays – Studies to track DNA recovery from various types of tubes– Characterizing potential SRM 2372 components (Human DNA
Quantitation Standard)
Margaret Kline
Amy Decker
Pete Vallone
http://www.cstl.nist.gov/biotech/strbase/DNAquant.htm
Importance of DNA Quantitation (prior to multiplex PCR)
-A
+AToo much DNA
Off-scale peaksSplit peaks (+/-A)Locus-to-locus imbalance
Too little DNAHeterozygote peak imbalanceAllele drop-outLocus-to-locus imbalance
DNA amount(log scale)
0.5 ng
100 ng
10 ng
1 ng
0.1 ng
0.01 ng
2.0 ng
Stochastic effect when amplifying low levels of DNA produces allele dropout
STR Kits Work Best in This Range
High levels of DNA create interpretation challenges (more artifacts to review)
Well-balanced STR multiplex
ABI 7500 Real-Time
PCR System
•96-well format thermal cycler •five-color detection system with CCD camera•Real-time monitoring of amplification growth curves enabling viewing of runs in progress
We also have access to ABI 7000 and 7900
instruments
Studies Performed
Human ID methods SYBR Green-based• Alu (high copy #)
– Nicklas & Buel (2003) J Forensic Sci 48 (5):936-944Human ID methods Probe based• CFS-HumRT
– Richard et al. (2003) J Forensic Sci 48(5):1041-1046• Quantifiler™ Human DNA Quantification Kit• Quantifiler™ Y Human Male Quantification Kit
– ABI Quantifiler Kits User’s Manual PN4344790• CA DOJ Duplex
– Timken et al., in press
45TaqManMGB
ND1 gene69 bpCA DOJ mito
45TaqManMGB
TH01170-190 bp CA DOJ nuclear
40TaqMan MGB
Sex determining region Y gene (SRY)
64 bpQfiler Y Male
40TaqMan MGB
Human telomerase reverse transcriptase gene (hTERT),
5p15.33
62 bpQfiler Human
40TH01Human tyrosine hydroxylase62 bpCFS-HUMRT 11p15.5
28-35NAAlu , Ya5 Subfamilygene124 bpAlu
#CyclesprobeGeneTargetampliconAssay
Assays Examined
2.0
1.6
1.2
1.3
1.0
Std5
1.52.01.62.01.5CA DOJ
1.82.01.93.11.7ALU
1.11.51.31.81.6CFS
1.2f1.32.01.7Quantifiler Y
0.91.21.02.31.5Quantifiler
Std6Std4Std3Std2Std1Assay
Experimental Design
Target concentration 1.6 ng/uL
1.96
1.62
1.17
1.31
0.99
Std5
1.461.981.562.011.51CA DOJ
1.782.001.873.081.68ALU
1.091.481.291.841.63CFS
1.15f1.262.011.67Quantifiler Y
0.911.150.952.281.54Quantifiler
Std6Std4Std3Std2Std1Assay
Experimental Design
Target concentration 1.6 ng/uL
Do the different methods agree for a single genomic DNA standard? (Assay bias)
How do different genomic DNA standards compare? (Standard bias)
Do observed concentration differences translate into significant signal variation in a human ID test? (RFUs)
SRM 2372
Human DNA Quantitation Standard(Tentative Information)
3 Samples Male, Female, Mixture
50 ng/µL
50 µL total volume
Available in 2006
STR Allele Sequencing and Characterization
• Variant characterization– TPOX 10.3 (Maryland State Police)– D18S51 null alleles (FSS and Kuwait govt)– D18S51 allele 40 (Nebraska State Crime Lab)– D18S51 allele 5.3 (DNA Solutions)– FGA allele 46.2 (Denver Crime Lab)– DYS392 allele “10.3” (AFDIL)
• Locus duplication or deletion– DYS390 (CFS Toronto)– DYS392 (MN BCA)
• Forensic labs are sending us unusual STR alleles for sequence characterization
Margaret Kline
John Butler
http://www.cstl.nist.gov/biotech/strbase/STRseq.htm
DNA ExtractionPCR
Amplification
Gel Separation
Allele Isolation with gel cutouts
DNA sequence analysis
12 GAAA repeats
Amplicon Quantitation
Re-Amplification
DNA Extraction
ExoSAP
Gel Cutouts with Heterozygotes
Cycle Sequencing
F/R Sequence Alignment to
Reference Sequence
Amplification with primers external
to kit primers
Dye Terminator Removal
Amplicon Quantitation
Re-Amplification
Steps in STR Allele SequencingSamples provided by collaborators or forensic practioners
Deletion results in a 10.3 allele call with PP 16 but an allele 11 call with COfiler/Identifiler/PP1.1.
TPOX Flanking Region Deletion Impacting Calls with Different Kits
MD state police
Analysis of Common STR Variant Alleles• We have monoplex primers for all common
STR loci and kits
• We have sequencing primers that bind outside of STR kit primer sequence positions to enable view of polymorphic nucleotides that cause primer binding site mutations
• NIJ has funded us to characterize STR variants for the forensic DNA community
D16S539 (bottom strand)
1 8765432 109 11
265
Mixture Interpretation Interlab Study (MIX05)
• Only involves interpretation of data• 91 labs enrolled for participation (20 from overseas)• 64 labs have returned results• Four mock cases supplied with “victim” and “evidence”
electropherograms (GeneScan .fsa files – that can be converted for Mac or GeneMapper; gel files made available to FMBIO labs)
• Data available with Profiler Plus, COfiler, SGM Plus, PowerPlex 16, Identifiler, PowerPlex 16 BIO (FMBIO) kits
• Summary of results with involve training materials to illustratevarious approaches to solving mixtures
Perpetrator Profile(s) ??
Along with reasons for making calls and any stats
that would be reported
Plans for Dissemination of MIX05 Results
• Data shipped in mid-January 2005• Responses due before March 15, 2005 (but still open)
• Goal is to understand the “lay of the land” regarding mixture analysis across the DNA typing community
• Results to be discussed at NIJ DNA Grantees Meeting (June 2005), SWGDAM (June 2005), and ISFG (Sept 2005)
• We plan to develop training materials to aid in mixture interpretation with available software tools and to help in standardizing reports involving mixture analysis
Software Tools
• AutoDimer – multiplex PCR primer screening tool
• mixSTR – mixture component resolution tool
• Multiplex_QA – quality assessment tool for monitoring instrument performance over time
• NIST U.S. population database (internal Access database)
Pete Vallone
Dave Duewer
Chris DeAngelis
http://www.cstl.nist.gov/biotech/strbase/AutoDimerHomepage/AutoDimerProgramHomepage.htm
http://www.cstl.nist.gov/biotech/strbase/software.htm
AutoDimer Primer Screening Program
Vallone, P.M. and Butler, J.M. (2004) BioTechniques 37:226-231
Available for download from STRBase:http://www.cstl.nist.gov/biotech/strbase
A web-based interface is in development
(similar to Primer3)
STRBase Updates
Primary updates performed monthly• Summary of variant alleles and tri-allelic patterns• List of STR references (Reference Manager database)
• NIST publications and presentations
• New content is being added regularly to aid training and to support forensic DNA laboratories
John Butler
Jan Redman
http://www.cstl.nist.gov/biotech/strbase/http://www.cstl.nist.gov/biotech/strbase/NISTpub.htmhttp://www.cstl.nist.gov/biotech/strbase/var_tab.htm
Content of STRBase Website
• …/str_fact.htm STR Fact Sheets on Core Loci• …/multiplx.htm Multiplex STR Kit Information• …/y_strs.htm Y-Chromosome Information• …/var_tab.htm Variant Alleles Reported• …/mutation.htm Mutation Rates for Common STRs• …/str_ref.htm Reference List with ~2,300 Papers• …/training.htm Downloadable PowerPoints for Training• …/validation.htm Validation Information• …/miniSTR.htm miniSTR Information• …/address.htm Addresses for Scientists• …/NISTpub.htm Publications & Presentations from NIST
http://www.cstl.nist.gov/biotech/strbase
Training Materials and Review Articles
• Workshops on STRs and CE (ABI 310/3100)– Taught with Bruce McCord (Florida Int. Univ.)– NEAFS (Sept 29-30, 2004)– U. Albany DNA Academy (June 13-14, 2005)
• PowerPoint slides from Forensic DNA Typing, 2nd Edition
• Review articles– ABI 310 and 3100 chemistry – Electrophoresis 2004, 25, 1397-1412– Forensic DNA analysis – Anal. Chem. 2005, 77, 3839-3860– STR core loci – J. Forensic Sci., in press (Nov 2005)
http://www.cstl.nist.gov/biotech/strbase/training.htmhttp://www.cstl.nist.gov/biotech/strbase/NISTpub.htm
John Butler
Interlaboratory Studies
• DNA Quantitation Study (QS04)– 8 DNA samples supplied– 84 laboratories signed up (80 labs returned results)– 287 data sets using 19 different methods– 60 data sets with real-time qPCR (37 Quantifiler data sets)– Publication in May 2005: J. Forensic Sci. 50(3): 571-578
• Mixture Interpretation Study (MIX05)– 91 labs signed up (64 labs returned data)– Interpretation requested of provided e-grams for 4 mock sexual
assault cases– Data analysis is still on-going…
http://www.cstl.nist.gov/biotech/strbase/interlab.htm
Dave Duewer
Margaret Kline
John Butler
Jan Redman
Team Impact on Forensic Community• 27 publications since June 2004 (61 since 2000)
• 31 presentations to the community since June 2004
• All NIST publications and presentations available on STRBase:http://www.cstl.nist.gov/biotech/strbase/NISTpub.htm
• Training materials: 2 workshops conducted with Bruce McCord– NEAFS (Sept 29-30, 2004)– Albany DNA Academy (June 13-14, 2005)– AAFS Workshop Seattle 2006
(Advanced Topics in STR DNA Analysis)
• Forensic DNA Typing: Biology, Technology, and Genetics of STR Markers, 2nd Edition (John Butler)
Acknowledgments
Mike Coble
Pete Vallone
John Butler
Margaret Kline
Amy Decker
Becky Hill
Dave Duewer
Jan Redman
Chris DeAngelis
Funding from interagency agreement 2003-IJ-R-029 between NIJ and the NIST Office of Law Enforcement Standards
Past and Present Collaborators (also funded by NIJ):Mike Hammer and Alan Redd (U. AZ) for Y-chromosome studiesTom Parsons, Rebecca Just, Jodi Irwin (AFDIL) for mtDNA coding SNP workSandy Calloway (Roche) for mtDNA LINEAR ARRAYsBruce McCord and students (FL Int. U.) for miniSTR workMarilyn Raymond and Victor David (NCI-Frederick) for cat STR workArtie Eisenberg and John Planz (U. North Texas)
Disclaimers and CollaborationsFunding: Interagency Agreement 2003-IJ-R-029 between the National Institute of Justice and NIST Office of Law Enforcement StandardsPoints of view are those of the authors and do not necessarily represent the official position or policies of the US Department of Justice. Certain commercial equipment, instruments and materials are identified in order to specify experimental procedures as completely as possible. In no case does such identification imply a recommendation or endorsement by the National Institute of Standards and Technology nor does it imply that any of the materials, instruments or equipment identified are necessarily the best available for the purpose.
Our publications and presentations are made available at: http://www.cstl.nist.gov/biotech/strbase/NISTpub.htm